Nonselective expression of simian virus 40 large tumor antigen fragments in mouse cells.

To understand the role of various functional domains of simian virus 40 early tumor antigens, we have cloned and introduced into mouse cells portions of early simian virus 40 DNA. Two types of truncated large tumor antigen (33 and 12.3 kilodaltons), as well as small tumor antigen, were identified by immunoprecipitation. Both truncated large tumor antigens have been found to be overproduced with respect to the small tumor antigen, although the 12.3-kilodalton truncated large tumor antigen was more stable than the 33-kilodalton one. Nonviral 53-kilodalton protein was not found associated with either truncated large tumor antigen in immunoprecipitations.     

Regulatory function of simian virus 40 DNA replication for late viral gene expression.

Inhibition of simian virus 40 (SV40) DNA synthesis prevents late but not early viral gene expression in infected cells. To test whether the late SV40 template specificity is elicited by replicative intermediate DNA molecules (RI-DNA), we isolated subcellular fractions containing RI-DNA from SV-40-infected monkey cells and microinjected these preparations into various cell lines under conditions in which viral DNA synthesis was blocked. Late SV40 gene expression (V-antigen synthesis) was obtained by microinjection of wild-type RI-DNA or temperature-sensitive mutant A7 RI-DNA preparations at 37 degrees or 41.5 degrees, respectively, while SV40 native superhelical DNA (DNA I) at a 10-fold higher concentration failed to induce V-antigen synthesis under the restrictive conditions. V-antigen synthesis was also obtained by microinjection of partially denatured SV40 DNA or a high number of randomly nicked DNA molecules (DNA II) in the absence of DNA synthesis; both single-stranded regions and nicks are specific features of RI-DNA molecules.     

Purification of simian virus 40 tumor antigen from a line of simian virus 40-transformed human cells.

Simian virus 40 tumor antigen can be isolated in a highly purified state from the nuclei ofSV80 cells, a continuous line of simian virus 40-transformed human fibroblasts. A five-step purification method was used. Its apparent molecular weight (in sodium dodecyl sulfate/polyacrylamide gels) is approximately 90,000-94,000. It contains a detectable amino-terminal residue.     

Purification of biologically active simian virus 40 small tumor antigen.

The simian virus 40 small tumor antigen (t antigen) gene has been cloned downstream from a hybrid Escherichia coli trp-lac promoter and a suitable ribosome binding site. A bacterial clone (865i) transformed by such a plasmid (pTR865) expresses this gene and, under optimal conditions, can produce greater than or equal to 5% of its total protein as t antigen. Soluble extracts of such a clone were relatively depleted in t antigen, which was found in the initial pellet fraction. The protein was recovered from this fraction in a significantly purified form by extraction with urea-containing buffer. After gel filtration of such t antigen-enriched solutions, highly purified protein was obtained. When either this fraction (freed of urea) or NaDodSO4 gel-purified 865i t antigen (rendered free of detergent) was injected into untransformed rat cells, dissolution of intracellular actin cable networks was observed.     

Complex of simian virus 40 large tumor antigen and 48,000-dalton host tumor antigen.

Simian virus 40 large tumor antigen (T Ag) can be separated by sucrose gradient sedimentation into a rapidly sedimenting, maximally phosphorylated fraction and a slowly sedimenting, less phosphorylated fraction. The Mr 48,000 host tumor antigen (48,000 HTA, also called nonviral T Ag) is preferentially complexed with the maximally phosphorylated T Ag. Pulse-labeled T Ag sediments as a 5-6S monomer, whereas T Ag radiolabeled for progressively longer periods slowly increases in sedimentation coefficient to give a broad distribution between 5 S and greater than 28 S. Mutation in the viral A locus causes a decrease in T Ag phosphorylation and a marked decrease in 48,000 HTA binding, shifting the sedimentation coefficient of T Ag to the monomer value. The more highly phosphorylated T Ag also has the highest affinity for chromatin.     

Differential affinities of simian virus 40 large tumor antigen for DNA.

The binding of simian virus 40 (SV40) large tumor antigen (T antigen) to DNA was analyzed by using the salt-sensitive affinities of the protein for various DNAs immobilized on cellulose. At least two types of interactions could be distinguished that differed in their stability. Higher salt concentrations were required to elute T antigen from SV40 DNA than from calf thymus DNA; and even greater salt concentrations were required for the lution of T antigen from multiorigin SV 40 DNA compared to wild-type SV40 DNA. This would indicate that T antigen can bind weakly or strongly to DNA, depending on the DNA sequence. It was also found that a greater proportion of rapidly labeled or newly synthesized T antigen binds more efficiently and tightly to multiorigin SV40 DNA than to long-labeled or older forms of T antigen. This approach can be utilized not only to distinguish between different forms of T antigens which vary in their affinities for DNA but also for rapidly obtaining highly enriched T antigen preparations.     

The simian virus 40 minimal origin and the 72-base-pair repeat are required simultaneously for efficient induction of late gene expression with large tumor antigen.

We have studied the temporal regulation of simian virus 40 (SV40) late gene expression by construction and transient expression analysis of plasmids containing the transposon Tn9 chloramphenicol acetyltransferase gene placed downstream from the late control region. The SV40 origin region in the early (but not the late) orientation promotes chloramphenicol acetyltransferase gene expression efficiently in monkey cells lacking large tumor (T) antigen. In monkey cells producing T antigen, the promoter activity of the late control region is induced by approximately 1,000-fold above the basal level. By deletion and point mutagenesis, we define two domains of the late control region required for efficient induction with T antigen. Domain I is the minimal replication origin containing T-antigen binding site II. Domain II consists of the 72-base-pair (bp) repeat and a 19-bp downstream sequence up to nucleotide 270. Domains I and II should act synergistically because the absence of either one or the other decreases induction efficiency by 2 orders of magnitude. Though a complete copy of domain II is optimal, the origin-proximal 22-bp portion of this domain is sufficient. The 21-bp repeat, located between domains I and II, is dispensable for this induction, as are sequences located downstream from nucleotide 270 in the late orientation.     

Photoreceptor degeneration induced by the expression of simian virus 40 large tumor antigen in the retina of transgenic mice.

Expression of the viral oncogene encoding the simian virus 40 (SV40) large tumor antigen (T antigen) typically promotes tumorigenesis in mammalian cells. To generate transgenic mice that express T antigen in rod photoreceptors, a chimeric construct consisting of a mouse opsin promoter fragment fused to the coding region of SV40 T antigen was generated. Expression of T antigen in the transgenic retina began at early stages of postnatal development concomitant with expression of endogenous opsin. Instead of inducing hyperplasia or tumor formation, T-antigen expression caused a rapidly progressing photoreceptor degeneration. The degeneration was accompanied by sustained DNA synthesis in photoreceptor cells, as evidenced by incorporation of [3H]thymidine and by the appearance of mitotic figures at postnatal day 10, a stage when nontransgenic photoreceptor cells are postmitotic and quiescent. Although transgenic photoreceptor cells undergo S phase and enter mitosis, the consequences of T-antigen expression are not proliferation and tumorigenesis but proliferation and cell death.     

Specific in vitro adenylylation of the simian virus 40 large tumor antigen.

Incubation of the simian virus 40 (SV40) large tumor antigen (T) from either transformed or lytically infected cells with adenosine [8-3H]-, [alpha-32P]-, or [alpha-[35S]thio]-triphosphate in the presence of Mg2+ resulted in its labeling as defined by the appearance of an intact, appropriately immunoreactive band in NaDodSO4/polyacrylamide gels. Radioactivity remained associated with the protein after boiling in buffer containing 3% NaDodSO4, and 2-mercaptoethanol as well as after heating in 0.1 M HCl, 0.1 M NH4OH, or hydroxylamine, but it was dissociated after incubation in 0.1 M NaOH at 37 degrees C. After limited boiling of gel-purified [alpha-32P] ATP + T complex in 5.6 M HCl, o-[32P]phosphoserine was released, and snake venom phosphodiesterase or 0.5 M piperidine treatment of such a complex resulted in the liberation of [alpha-32P]AMP. The reaction proceeded when either purified, soluble T or insoluble, specifically immunoprecipitated antigen was used as substrate. ATP and dATP were the preferred nucleotide substrates by comparison with the other six standard ribonucleoside or deoxynucleoside triphosphates. Partial tryptic digests of T + [alpha-32P]ATP complexes revealed the presence of a single labeled peptide of Mr approximately equal to 12 - 14 X 10(3), and after exhaustive digestion, there was a single radioactive spot in the fingerprint. These data indicate that T can be adenylylated at a specific seryl residue(s) in a limited portion of the protein surface. Furthermore, adenylylation appears to be reversible and to proceed by a pyrophosphorylytic mechanism, since the nucleotide was released from the protein following incubation of adenylylated T with Mg2+, sodium pyrophosphate, and poly(dT).     

Signal-mediated nuclear transport in simian virus 40-transformed cells is regulated by large tumor antigen.

Transformation of cultured cells with simian virus 40 (SV40), or transfection with the early region of the SV40 genome, causes a significant increase in both the rate of signal-mediated nuclear transport and the functional size of the transport channels (located in the pore complexes). By microinjecting purified large tumor (T) antigen into the cytoplasm of murine BALB/c 3T3 cells, we have demonstrated that this protein alone can account for the increase in transport capacity. The T antigen-dependent changes can be partially inhibited by cycloheximide and require a functional nuclear localization sequence. Although necessary, the nuclear localization sequence by itself cannot produce the observed variations in nuclear permeability and presumably function in a "helper" capacity, in association with another, as yet unidentified domain.     

Mapping of the late promoter of simian virus 40.

Mapping of the simian virus 40 (SV40) late promoter was carried out in the absence of the viral early protein, large tumor (T) antigen, and replication of the viral DNA template. SV40 late control region DNA fragments, containing specific deletions, were cloned directly upstream from the coding region of the herpes simplex virus-1 (HSV-1) thymidine kinase (TK; ATP:thymidine 5'-phosphotransferase, EC 2.7.1.21) gene (tk). The promoter activities of the fragments were determined by measuring the tk transformation frequencies of the chimeric tk constructs in mouse L TK- APRT- (adenine phosphoribosyltransferase-negative) and human 143B TK- cell lines. The following results were obtained. (i) The SV40 control region functions with equal efficiencies in the early and late promoter orientations. (ii) A major late control element has been localized within the G+C-rich 21-base-pair (bp) repeat. Thus, in conjunction with our earlier results, the 21-bp repeat is a bidirectional promoter element functioning as a major component of both the early and late promoters and is an element that enhances the replication efficiency of SV40 DNA. (iii) Minor late promoters have been localized within the minimal replication origin and the 72-bp repeat. (iv) The minimal replication origin is not per se a constituent of the major late promoter; however, both the minimal replication origin and the 21-bp repeat are required for obtaining high levels of late gene expression observed at late times after infection by SV40. (v) The 72-bp repeat exerts a 4- to 5-fold enhancement of late promoter expression.     

Methylation of simian virus 40 Hpa II site affects late, but not early, viral gene expression.

DNA methylation has been correlated with reduced gene expression in a number of studies, although evidence for a casual link between the two events has been lacking. Because microinjection of simian virus 40 (SV40) DNA into the nucleus of Xenopus laevis oocytes results in the synthesis of both early and late viral gene products, it was possible to test whether a specific methylation event can affect gene expression. The single SV40 Hpa II site at 0.72 SV40 map units was specifically methylated with Hpa II methylase. When this DNA was injected into oocytes, there was a marked reduction in the synthesis of the major late viral capsid protein VP-1, relative to the synthesis by an unmethylated control. However, production of the early proteins (the large and small tumor antigens) was not affected by Hpa II methylation. Therefore, methylation at a single site on the viral DNA located near the 5' end of the late region can specifically repress late gene expression. The possible mechanisms by which this repression is mediated are discussed.     

Nature and origin of the RNA associated with simian virus 40 large tumor antigen.

Simian virus 40 (SV40) large tumor (T) antigen isolated from mammalian cells undergoing lytic or transforming infection is associated with small RNA fragments ("T-antigen RNA") that are protected from nuclease digestion. The rather high complexity of the ribonuclease T1 fingerprints of T-antigen RNA suggested that it is mainly derived from cellular heterogeneous nuclear RNAs. In the present study, 5'-32P-labeled T-antigen RNA was hybridized to monkey, mouse, and human Alu and SV40 DNA, and the nucleotide sequence of 37 T1 oligonucleotides was determined. The results suggest that the bulk of T-antigen RNA is derived from noncoding, double-stranded, ordered regions of cellular heterogeneous nuclear RNAs that exhibit sequence homologies with interspersed repetitive elements of the cellular genome. The possible biological implications of these results are discussed.     

Somatic cell hybrids producing antibodies specific for the tumor antigen of simian virus 40.

We have produced somatic cell hybrids between mouse myeloma cells deficient in hypoxanthine phosphoribosyltransferase IMP: pyrophosphate phosphoribosyltransferase; EC 2.4.2.8) and spleen cells derived from mice primed with either syngeneic or allogeneic cells transformed by simian virus 40. Such hybrids produced antibodies specific for simian virus 40 tumor (T) antigen. Only four of twelve independent hybrid cell cultures produced antibodies against simian virus 40 T antigen that crossreacted with the T antigen induced by BK virus, a human papovavirus isolated from patients who had undergone immunosuppressive therapy.